This invention relates generally to non-wetting and low adhesion surfaces. More particularly, in certain embodiments, the invention relates to non-wetting, liquid-impregnated surfaces that are engineered to eliminate pinning and/or to either avoid or induce cloaking.
The advent of micro/nano-engineered surfaces in the last decade has opened up new techniques for enhancing a wide variety of physical phenomena in thermofluids sciences. For example, the use of micro/nano surface textures has provided nonwetting surfaces capable of achieving less viscous drag, reduced adhesion to ice and other materials, self-cleaning, and water repellency. These improvements result generally from diminished contact (i.e., less wetting) between the solid surfaces and adjacent liquids.
One type of non-wetting surface of interest is a superhydrophobic surface. In general, a superhydrophobic surface includes micro/nano-scale roughness on an intrinsically hydrophobic surface, such as a hydrophobic coating. Superhydrophobic surfaces resist contact with water by virtue of an air-water interface within the micro/nano surface textures.
One of the drawbacks of existing non-wetting surfaces (e.g., superhydrophobic, superoleophobic, and supermetallophobic surfaces) is that they are susceptible to impalement, which destroys the non-wetting capabilities of the surface. Impalement occurs when an impinging liquid (e.g., a liquid droplet or liquid stream) displaces the air entrained within the surface textures. Previous efforts to prevent impalement have focused on reducing surface texture dimensions from micro-scale to nano-scale.
Although not well recognized in previous studies of liquid-impregnated surfaces, the impregnating liquid may spread over and “cloak” the contacting liquid (e.g., water droplets) on the surface. For example, cloaking can cause the progressive loss of impregnating liquid through entrainment in the water droplets as they are shed from the surface.
Frost formation is another problem affecting a large variety of industries, including transportation, power generation, construction, and agriculture. The effects of frosting may lead to downed power lines, damaged crops, and stalled aircrafts. Moreover, frost and ice accumulation significantly decreases the performance of ships, wind turbines, and HVAC systems. Currently used active chemical, thermal, and mechanical techniques of ice removal are time consuming and costly in operation. Development of passive methods preventing frost and ice accretion is highly desirable. Hydrophobic surfaces have a high energy barrier for ice nucleation and low ice adhesion strength and, if properly roughened on the nano- and/or micro-scales, can repel impact of supercooled water droplets. However, the anti-icing properties of hydrophobic as well as superhydrophobic surfaces are negated once the surfaces are frosted. Frost formation and ice adhesion can also be reduced by addition of a liquid or grease onto the working surface. For example, ice adhesion to aircraft surfaces is significantly reduced through application of silicone grease, and frost formation can be prevented on exterior of freezers and heat exchangers coated with a 100 μm porous layer infused with propylene glycol antifreeze. However, in both of these cases the non-solid phases are sacrificial and can leak into the surroundings causing significant environmental problems.
There is a need for non-wetting surfaces that are robust and/or deliver optimal non-wetting properties and resist frost formation.
Described herein are non-wetting surfaces that include a liquid impregnated within a matrix of micro/nano-engineered features on the surface, or a liquid filling pores or other tiny wells on the surface. In certain embodiments, compared to previous non-wetting surfaces, which include a gas (e.g., air) entrained within the surface textures, these liquid-impregnated surfaces are resistant to impalement and frost formation, and are therefore more robust.
Impregnating fluids that cover the tops of the matrix of solid features offer a non-wetting benefit. However, at equilibrium, the impregnating liquid may not cover the tops of solid features (e.g., microposts or nanograss) of the surface without being continually replenished. Furthermore, while certain impregnating fluids do cover the tops of solid features, offering a non-wetting benefit, they often exhibit cloaking, and the impregnating fluid is depleted unless replenished.
It is discovered that liquid-impregnated surfaces can be engineered to provide resistance to impalement and to provide non-wettability, without requiring replenishment of impregnating fluid to make up for liquid lost to cloaking, and without requiring replenishment of impregnating liquid to maintain coverage over the tops of the solid features.
In one aspect, the invention is directed to an article comprising a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) 0<φ≦0.25, where φ is a representative fraction of the projected surface area of the liquid-impregnated surface corresponding to non-submerged solid (i.e., non-submerged by the impregnating liquid, e.g., can be “non-submerged” and still in contact with water) at equilibrium (e.g., where equilibrium can encompass pseudo-equilibrium); and (ii) Sow(v)<0, where Sow(v) is spreading coefficient, defined as γwv−γwo−γov, where γ is the interfacial tension between the two phases designated by subscripts, said subscripts selected from w, v, and o, where w is water, v is vapor phase in contact with the surface (e.g., air), and o is the impregnating liquid.
In some embodiments, 0<φ≦0.25, or 0.01<φ≦0.25, or 0.05<φ≦0.25. In some embodiments, Sow(v)<0.
In some embodiments, the impregnating liquid comprises at least one member selected from the group consisting of silicone oil, propylene glycol dicaprylate/dicaprate, perfluoropolyether (PFPE), polyalphaolefin (PAO), synthetic hydrocarbon cooligomer, fluorinated polysiloxane, propylene glycol, tetrachloroethylene (perchloroethylene), phenyl isothiocyanate (phenyl mustard oil), bromobenzene, iodobenzene, o-bromotoluene, alpha-chloronaphthalene, alpha-bromonaphthalene, acetylene tetrabromide, 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (BMIm), tribromohydrin (1,2,3-tribromopropane), ethylene dibromide, carbon disulfide, bromoform, methylene iodide (diiodomethane), stanolax, Squibb's liquid petrolatum, p-bromotoluene, monobromobenzene, perchloroethylene, carbon disulfide, phenyl mustard oil, monoiodobenzene, alpha-monochloro-naphthalene, acetylene tetrabromide, aniline, butyl alcohol, isoamyl alcohol, n-heptyl alcohol, cresol, oleic acid, linoleic acid, and amyl phthalate.
In some embodiments, the solid features comprise at least one member selected from the group consisting of a polymeric solid, a ceramic solid, a fluorinated solid, an intermetallic solid, and a composite solid. In some embodiments, the solid features comprise a chemically modified surface, coated surface, surface with a bonded monolayer. In some embodiments, the solid features define at least one member selected from the group consisting of pores, cavities, wells, interconnected pores, and interconnected cavities. In some embodiments, the solid features comprise at least one member selected from the group consisting of posts, nanoneedles, nanograss, substantially spherical particles, and amorphous particles. In some embodiments, the solid features have a rough surface (e.g., the solid features have a surface roughness>50 nm, >100 nm, e.g., and also <1 μm). In some embodiments, the rough surface provides stable impregnation of liquid therebetween or therewithin, such that θos(v),receding<θc, where θc is critical contact angle.
In some embodiments, the liquid-impregnated surface is configured such that water droplets contacting the surface are not pinned or impaled on the surface and have a roll-off angle α of less than 40°. In some embodiments, the water droplets have a roll-off angle α of less than 35°, less than 30°, less than 25°, or less than 20°.
In another aspect, the invention is directed to an article comprising a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) θos(w),receding=0; and (ii) θos(v),receding=0 and θos(w),receding=0, where θos(w),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of water (subscript ‘w’), and where θos(v),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of vapor phase (subscript ‘v’, e.g., air).
In another aspect, the invention is directed to a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) θos(v),receding>0; and (ii) θos(w),receding>0, where θos(v),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of vapor phase (subscript ‘v’, e.g., air), and where θos(w),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of water (subscript ‘w’).
In some embodiments, both θos(v),receding>0 and θos(w),receding>0. In some embodiments, one or both of the following holds: (i) θos(v),receding<θc; and (ii) θos(w),receding<θc, where θc is critical contact angle. In some embodiments, one or both of the following holds: (i) θos(v),receding<θ*c; and (ii) θos(w),receding<θ*c, where θ*c=cos−1(1/r), and where r is roughness of the solid portion of the surface.
In some embodiments, the article is a member selected from the group consisting of a pipeline, a steam turbine part, a gas turbine part, an aircraft part, a wind turbine part, eyeglasses, a mirror, a power transmission line, a container, a windshield, an engine part, a nozzle, a tube, or a portion or coating thereof.
In another aspect, the invention is directed to an article comprising an interior surface, said article being at least partially enclosed (e.g., the article is an oil pipeline, other pipeline, consumer product container, other container) and adapted for containing or transferring a fluid of viscosity μ1, wherein the interior surface comprises a liquid-impregnated surface, said liquid-impregnated surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein the impregnating liquid comprises water (having viscosity μ2).
In some embodiments, μ1/μ2>1. In some embodiments, μ1/μ2>0.1. In some embodiments, (h/R)(μ1/μ2)>0.1 (where h is average height of the solid features and R is the radius of the pipe or the average fluid depth in an open system). In some embodiments, (h/R)(μ1/μ2)>0.5. In some embodiments, R<1 mm.
In some embodiments, the impregnating liquid comprises an additive (e.g., a surfactant) to prevent or reduce evaporation of the impregnating liquid. In some embodiments, said surface comprises a pulled-up region of excess impregnating liquid (e.g., oil) extending above said solid features.
In another aspect, the invention is directed to an article comprising a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) 0<φ≦0.25, where φ is a representative fraction of the projected surface area of the liquid-impregnated surface corresponding to non-submerged solid (i.e., non-submerged by the impregnating liquid—can be “non-submerged” and still in contact with the non-vapor phase external to the surface) at equilibrium (e.g., where equilibrium can encompass pseudo-equilibrium); and (ii) Soe(v)<0, where Soe(v) is spreading coefficient, defined as γev−γeo−γov, where γ is the interfacial tension between the two phases designated by subscripts, said subscripts selected from e, v, and o, where e is a non-vapor phase (e.g., liquid or semi-solid) external to the surface and different from the impregnating liquid, v is vapor phase external to the surface (e.g., air), and o is the impregnating liquid.
In some embodiments, 0<φ≦0.25. In some embodiments, 0.01<φ≦0.25. In some embodiments, 0.05<φ≦0.25. In some embodiments, Soe(v)<0.
In some embodiments, the impregnating liquid comprises at least one member selected from the group consisting of silicone oil, propylene glycol dicaprylate/dicaprate, perfluoropolyether (PFPE), polyalphaolefin (PAO), synthetic hydrocarbon cooligomer, fluorinated polysiloxane, propylene glycol, tetrachloroethylene (perchloroethylene), phenyl isothiocyanate (phenyl mustard oil), bromobenzene, iodobenzene, o-bromotoluene, alpha-chloronaphthalene, alpha-bromonaphthalene, acetylene tetrabromide, 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (BMIm), tribromohydrin (1,2,3-tribromopropane), ethylene dibromide, carbon disulfide, bromoform, methylene iodide (diiodomethane), stanolax, Squibb's liquid petrolatum, p-bromotoluene, monobromobenzene, perchloroethylene, carbon disulfide, phenyl mustard oil, monoiodobenzene, alpha-monochloro-naphthalene, acetylene tetrabromide, aniline, butyl alcohol, isoamyl alcohol, n-heptyl alcohol, cresol, oleic acid, linoleic acid, and amyl phthalate.
In some embodiments, the solid features comprise at least one member selected from the group consisting of a polymeric solid, a ceramic solid, a fluorinated solid, an intermetallic solid, and a composite solid. In some embodiments, the solid features comprise a chemically modified surface, coated surface, surface with a bonded monolayer. In some embodiments, the solid features define at least one member selected from the group consisting of pores, cavities, wells, interconnected pores, and interconnected cavities. In some embodiments, the solid features comprise at least one member selected from the group consisting of posts, nanoneedles, nanograss, substantially spherical particles, and amorphous particles. In some embodiments, the solid features have a rough surface (e.g., the solid features have a surface roughness<1 μm). In some embodiments, the rough surface provides stable impregnation of liquid therebetween or therewithin, such that θos(v),receding<θc, where θc is critical contact angle. In some embodiments, the liquid-impregnated surface is configured such that water droplets contacting the surface are not pinned or impaled on the surface and have a roll-off angle α of less than 40°. In some embodiments, the water droplets have a roll-off angle α of less than 35°, less than 30°, less than 25°, or less than 20°.
In another aspect, the invention is directed to an article comprising a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) θos(e),receding=0; and (ii) θos(v),receding=0 and θos(e),receding=0, where θos(e),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of a non-vapor (e.g., liquid, solid, semi-solid, gel) phase external to the surface that is different from the impregnating liquid (subscript ‘e’), and where θos(v),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of vapor phase (subscript ‘v’, e.g., air).
In another aspect, the invention is directed to an comprising a liquid-impregnated surface, said surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein one or both of the following holds: (i) θos(v),receding>0; and (ii) θos(e),receding>0, where θos(v),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of vapor phase (subscript ‘v’, e.g., air), and where θos(e),receding is receding contact angle of the impregnating liquid (e.g., oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of a non-vapor (e.g., liquid, solid, semi-solid, gel) phase external to the surface that is different from the impregnating liquid (subscript ‘e’).
In some embodiments, both θos(v),receding>0 and θos(e),receding>0. In some embodiments, one or both of the following holds: (i) θos(v),receding<θc; and (ii) θos(e),receding<θc, where θc is critical contact angle. In some embodiments, one or both of the following holds: (i) θos(v),receding<θ*c; and (ii) θos(e),receding<θc, where θ*c=cos−1(1/r), and where r is roughness of the solid portion of the surface.
In some embodiments, the article is a member selected from the group consisting of a pipeline, a steam turbine part, a gas turbine part, an aircraft part, a wind turbine part, eyeglasses, a mirror, a power transmission line, a container, a windshield, an engine part, tube, nozzle, or a portion or coating thereof. In some embodiments, said surface comprises a pulled-up region of excess impregnating liquid (e.g., oil) extending above said solid features.
In some embodiments of any of the aspects described herein (e.g., herein above), the article further comprises material of said non-vapor phase external to said surface (and in contact with said surface), said article containing said non-vapor phase material [e.g. wherein the article is a container, a pipeline, nozzle, valve, a conduit, a vessel, a bottle, a mold, a die, a chute, a bowl, a tub, a bin, a cap (e.g., laundry detergent cap), and/or a tube]. In some embodiments, said material of said non-vapor phase external to said surface comprises one or more of the following: food, cosmetic, cement, asphalt, tar, ice cream, egg yolk, water, alcohol, mercury, gallium, refrigerant, toothpaste, paint, peanut butter, jelly, jam, mayonnaise, ketchup, mustard, condiment, laundry detergent, consumer product, gasoline, petroleum product, oil, biological fluid, blood, plasma.
In another aspect, the invention is directed to a method of using any article described herein (e.g., herein above), the method comprising the step of exposing said surface to water.
In another aspect, the invention is directed to a method of using the article of any one of claims 28 to 47, the method comprising the step of exposing said surface to said non-vapor phase (e.g., liquid or semi-solid) external to the surface and different from the impregnating liquid. In some embodiments, the non-vapor phase comprises one or more of the following: food, cosmetic, cement, asphalt, tar, ice cream, egg yolk, water, alcohol, mercury, gallium, refrigerant, toothpaste, paint, peanut butter, jelly, jam, mayonnaise, ketchup, mustard, condiment, laundry detergent, consumer product, gasoline, petroleum product, oil, biological fluid, blood, plasma.
The objects and features of the invention can be better understood with reference to the drawing described below, and the claims.
a) illustrates a schematic diagram of a liquid droplet placed on a textured surface impregnated with a lubricant that wets the solid completely.
b) illustrates a schematic diagram of a liquid droplet placed on a textured surface impregnated with a lubricant that wets the solid with a non-zero contact angle in the presence of air and the droplet liquid.
c) illustrates a water droplet on a silicon micro post surface (post side a=10 μm, height=10 μm, and spacing b=10 μm) coated with OTS (octadecyltrichlorosilane) and impregnated with silicone oil.
d) illustrates a water droplet on a silicon micro post surface (post side a=10 μm, height=10 μm, and spacing b=10 μm) coated with OTS (octadecyltrichlorosilane) and impregnated with 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide (BMIm).
e) and 1(f) illustrate a water droplet under UV illumination when a fluorescent dye was dissolved in silicone oil and BMIm. The bottom regions show that the lubricating oils are pulled up above the texture surface (b=50 μm).
g) and 1(h) show laser confocal fluorescence microscopy (LCFM) images of the impregnated texture showing that post tops were bright in the case of silicone oil (FIG. 1(g)), suggesting that they were covered with oil, and were dark in the case of BMIm (
i) illustrates an ESEM image of the impregnated texture showing the silicone oil trapped in the texture and suggesting that the film that wets the post tops is thin.
j) illustrates a SEM image of the texture impregnated with BMIm showing discrete droplets on post tops indicating that a film was not stable in this case.
k) illustrates schematics of wetting configurations outside and underneath a drop. The total interface energies per unit area are calculated for each configuration by summing the individual interfacial energy contributions. Equivalent requirements for stability of each configuration are also shown in
a) illustrates measured velocities of water droplets as a function of substrate tilt angle for various lubricant viscosities, post spacings, and droplet sizes.
b) is a schematic of a water droplet moving on a lubricant-impregnated surface showing the various parameters considered in the scaling model.
c) illustrates trajectories of a number of coffee particles measured relative to the water droplet revealing that the drop rolls rather than slips across the surface.
d) is a non-dimensional plot that collapses the data points shown in
a) shows measured roll-off angles for different encapsulating liquids as a function of post spacing b, according to some embodiments described herein. Extremely low roll-off angles were observed in some embodiments in the case of silicone oil impregnated surfaces, consistent with the post tops being encapsulated both outside and underneath the droplet (state A3-W3, θos(a), θos,w=0). The high roll-off angles seen in the case of BMIm impregnated surfaces are consistent with the post tops being emergent outside and underneath the droplet (state A2-W2, θc>θos(a), θos(w)>0).
b) shows an SEM image of the BMIm impregnated texture and reveals that the post tops are dry, in accordance with certain embodiments of the invention.
c) shows an SEM image of the posts that are further roughened by adding nanograss, the posts are covered with BMIm and consequently, the roll-off angle decreases, in accordance with certain embodiments of the invention.
d) shows a non-dimensional plot of scaled gravitational force (left side of Eq. (11) discussed below) at the instant of roll-off as a function of the relevant pinning force (right side of Eq. (11) discussed below), demonstrating that the roll-off data is in general agreement with the scaling, in accordance with certain embodiments of the invention.
a) is a SEM image of a silicon micropost array, in accordance with certain embodiments of the invention.
b) is a SEM image of silicon microposts etched with nanograss, in accordance with certain embodiments of the invention.
It is contemplated that compositions, mixtures, systems, devices, methods, and processes of the claimed invention encompass variations and adaptations developed using information from the embodiments described herein. Adaptation and/or modification of the compositions, mixtures, systems, devices, methods, and processes described herein may be performed by those of ordinary skill in the relevant art.
Throughout the description, where articles, devices, apparatus and systems are described as having, including, or comprising specific components, or where processes and methods are described as having, including, or comprising specific steps, it is contemplated that, additionally, there are articles, devices, apparatus and systems of the present invention that consist essentially of, or consist of, the recited components, and that there are processes and methods according to the present invention that consist essentially of, or consist of, the recited processing steps.
Similarly, where articles, devices, mixtures, apparatus and compositions are described as having, including, or comprising specific compounds and/or materials, it is contemplated that, additionally, there are articles, devices, mixtures, apparatus and compositions of the present invention that consist essentially of, or consist of, the recited compounds and/or materials.
It should be understood that the order of steps or order for performing certain actions is immaterial so long as the invention remains operable. Moreover, two or more steps or actions may be conducted simultaneously.
The mention herein of any publication, for example, in the Background section, is not an admission that the publication serves as prior art with respect to any of the claims presented herein. The Background section is presented for purposes of clarity and is not meant as a description of prior art with respect to any claim.
Surfaces with designed chemistry and roughness possess remarkable non-wetting properties, which can be very useful in a wide variety of commercial and technological applications, as will be described in further detail below.
In some embodiments, where “a” is used as a subscript of a variable to denote air, “v” is also appropriate (where v indicates a vapor phase). Also, where “w” as a subscript of a variable to denote water, “e” is also appropriate (where e indicates a non-vapor (e.g., liquid, solid, semi-solid, gel) phase external to the surface that is different from the impregnating liquid.
In some embodiments, a non-wetting, liquid-impregnated surface is provided that includes a solid having textures (e.g., posts) that are impregnated with an impregnating liquid. In some embodiments, the lubricant is stabilized by the capillary forces arising from the microscopic texture, and provided that the lubricant wets the solid preferentially, this allows the droplet to move (e.g., slide, roll, slip, etc.) above the liquid-impregnated surface with remarkable ease, as evidenced by the extremely low contact angle hysteresis (˜1°) of the droplet. In some embodiments, in addition to low hysteresis, these non-wetting surfaces can provide self-cleaning properties, withstand high drop impact pressures, self-heal by capillary wicking upon damage, repel a variety of liquids, and reduce ice adhesion. Contact line morphology governs droplet pinning and hence its mobility on the surface.
In general, solid features can be made from or can comprise any material suitable for use in accordance with the present invention. In accordance with various embodiments of the present invention, micro-scale solid features are used (e.g., from about 1 micron to about 100 microns in characteristic dimension, e.g., from about 1-10 microns, 10-20 microns, 20-30 microns, 30-50 microns, 50-70 microns, 70-100 microns). In certain embodiments, nano-scale solid features are used (e.g., less than about 1 micron, e.g., about 1 nm to about 1 micron e.g., about 1-10 nm, 10-50 nm, 50-100 nm, 100-200 nm, 200-300 nm, 300-500 nm, 500-700 nm, 700 nm-1 micron).
In some embodiments, micro-scale features are used. In some embodiments, a micro-scale feature is a particle. Particles can be randomly or uniformly dispersed on a surface. Characteristic spacing between particles can be about 200 μm, about 100 μm, about 90 μm, about 80 μm, about 70 μm, about 60 μm, about 50 μm, about 40 μm, about 30 μm, about 20 μm, about 10 μm, about 5 μm or 1 μm. In some embodiments, characteristic spacing between particles is in a range of 100 μm-1 μm, 50 μm-20 μm, or 40 μm-30 μm. In some embodiments, characteristic spacing between particles is in a range of 100 μm-80 μm, 80 μm-50 μm, 50 μm-30 μm or 30 μm-10 μm. In some embodiments, characteristic spacing between particles is in a range of any two values above.
Particles can have an average dimension of about 200 μm, about 100 μm, about 90 μm, about 80, about 70 μm, about 60 μm, about 50 μm, about 40 μm, about 30 μm, about 20 μm, about 10 μm, about 5 μm or 1 μm. In some embodiments, an average dimension of particles is in a range of 100 μm-1 μm, 50 μm-10 μm, or 30 μm-20 μm. In some embodiments, an average dimension of particles is in a range of 100 μm-80 μm, 80 μm-50 μm, 50 μm-30 μm or 30 μm-10 μm. In some embodiments, an average dimension of particles is in a range of any two values above.
In some embodiments, particles are porous. Characteristic pore size (e.g., pore widths or lengths) of particles can be about 5000 nm, about 3000 nm, about 2000 nm, about 1000 nm, about 500 nm, about 400 nm, about 300 nm, about 200 nm, about 100 nm, about 80 nm, about 50, about 10 nm. In some embodiments, characteristic pore size is in a range of 200 nm-2 μm or 100 nm-1 μm. In some embodiments, characteristic pore size is in a range of any two values above.
In some embodiments, the liquid-impregnated surface is configured such that water droplets contacting the surface are not pinned or impaled on the surface.
As used herein, emerged area fraction φ is defined as a representative fraction of the projected surface area of the liquid-impregnated surface corresponding to non-submerged solid at equilibrium. The term “equilibrium” as used herein refers to the condition in which the average thickness of the impregnating film does not change over time due to drainage by gravity when the substrate is held away from horizontal, and where evaporation is negligible (e.g., if the liquid impregnated liquid were to be placed in an environment saturated with the vapor of that impregnated liquid). Similarly, the term “pseudo-equilibrium” as used herein refers to equilibrium with the condition that evaporation may occur or gradual dissolving may occur. Note that the average thickness of a film at equilibrium may be less on parts of the substrate that are at a higher elevation, due to the decreased hydrostatic pressure within the film at increasing elevation. However, it will eventually reach an equilibrium (or pseudo-equilibrium), in which the average thickness of any part of the surfaces is unchanging with time.
In general, a “representative fraction” of a surface refers to a portion of the surface with a sufficient number of solid features thereupon such that the portion is reasonably representative of the whole surface. In certain embodiments, a “representative fraction” is at least a tenth of the whole surface.
Referring to
In certain embodiments of the present invention, φ is less than 0.30, 0.25, 0.20, 0.15, 0.10, 0.05, 0.01, or 0.005. In certain embodiments, φ is greater than 0.001, 0.005, 0.01, 0.05, 0.10, 0.15, or 0.20. In certain embodiments, φ is in a range of about 0 and about 0.25. In certain embodiments, φ is in a range of about 0 and about 0.01. In certain embodiments, φ is in a range of about 0.001 and about 0.25. In certain embodiments, φ is in a range of about 0.001 and about 0.10.
In some embodiments, the liquid-impregnated surface is configured such that cloaking by the impregnating liquid can be either eliminated or induced, according to different embodiments described herein.
As used herein, the spreading coefficient, Sow(a), is defined as γwa−γwo−γoa, where γ is the interfacial tension between the two phases designated by subscripts w, a, and o, where w is water, a is air, and o is the impregnating liquid. Interfacial tension can be measured using a pendant drop method as described in Stauffer, C. E., “The measurement of surface tension by the pendant drop technique,” J. Phys. Chem. 1965, 69, 1933-1938, the text of which is incorporated by reference herein. Exemplary surfaces and its interfacial tension measurements (at approximately 25° C.) are Table 3 below.
Without wishing to be bound to any particular theory, impregnating liquids that have Sow(a), less than 0 will not cloak matter as seen in
c) illustrates a water droplet on a silicon micro post surface (post side a=10 μm, height=10 μm, and spacing b=10 μm) coated with OTS (octadecyltrichlorosilane) and impregnated with silicone oil.
c) shows an 8 μl water droplet placed on the silicone oil impregnated texture. The droplet forms a large apparent contact angle (˜100°) but very close to the solid surface (shown by arrows in
When a fluorescent dye was added to the silicone oil and imaged under UV light, the point of inflection corresponded to the height to which an annular ridge of oil was pulled up in order to satisfy a vertical force balance of the interfacial tensions at the inflection point (
The texture can be completely submerged in the oil if θos(a)=0°. This condition was found to be true for silicone oil, implying that the tops of the posts should be covered by a stable thin oil film. This film was observed experimentally using laser confocal fluorescence microscopy (LCFM); the post tops appear bright due to the presence of a fluorescent dye that was dissolved in the oil (
The stable wetting configuration affects the mobility of droplets. As shown in
A thermodynamic framework that allows one to predict which of these 12 states will be stable for a given droplet, oil, and substrate material will be discussed in the paragraphs below. There are three possible configurations to consider for the interface outside of the droplet (in an air environment), and three possible configurations to consider for the interface underneath the droplet (in a water environment). These configurations are shown in
E
A2
<E
A1
(γsa−γos)/γoa>(1−φ)/(r−φ) (1)
E
A2
<E
A3
γsa−γos−γoa<0 (2)
where φ is the fraction of the projected area of the surface that is occupied by the solid and r is the ratio of total surface area to the projected area of the solid. In the case of square posts with width “a”, edge-to-edge spacing “b”, and height “h”, φ=a2/(a+b)2 and r=1+4ah/(a+b)2. Applying Young's equation, cos(θos(a))=(γsa−γos)/γoa, Eq. (1) reduces to the hemi-wicking criterion for the propagation of oil through a textured surface: cos(θos(a))>(1−φ)/(r−φ)=cos(θc). This requirement can be conveniently expressed as θos(a)<θc. In Eq. (2), γsa−γos−γoa, is simply the spreading coefficient Sos(a) of oil on the textured surface in the presence of air. This may be reorganized as (γsa−γos)/γoa<1, and applying Young's equation again, Eq. (2) can be written as θos(a)>0. Expressing Eq. (1) in terms of the spreading coefficient Sos(a), yields: −γoa(r−1)/(r−φ)<Sos(a). The above simplifications then lead to the following equivalent criteria for the surface to be in state A2:
E
A2
<E
A1
,E
A3
θc>θos(a)>0γoa(r−1)/(r−φ)<Sos(a)<0 (3)
Similarly, state A3 would be stable if EA3<EA2, EA1. From
E
A3
<E
A2
θos(a)=0γsa−γoa≡Sos(a)≧0 (4)
E
A3
<E
A1
θos(a)<cos−1(1/r)Sos(a)>−γoa(1/1/r) (5)
Note that Eq. (5) is automatically satisfied by Eq. (4), thus the criterion for state A3 to be stable (i.e., encapsulation) is given by Eq. (4). Following a similar procedure, the condition for state A1 to be stable can be derived as
E
A1
<E
A2
,E
A3
θos(a)>θcSos(a)<−γoa(r−1)/(r−φ) (6)
The rightmost expression of Eq. (4) can be rewritten as (γsa−γos)/γoa≧1. This raises an important point: Young's equation would suggest that if θos(a)=0, then (γsa−γos)/γoa=1 (i.e., Sos(a)=0). However, θos(a)=0 is true also for the case that (γsa−γos)/γoa>1 (i.e. Sos(a)>0). It is important to realize that Young's equation predicts the contact angle based on balancing the surface tension forces on a contact line—the equality only exists for a contact line at static equilibrium. For a spreading film (Sos(a)>0) a static contact line doesn't exist, hence precluding the applicability of Young's equation.
The configurations possible underneath the droplet are discussed in the paragraphs below. Upon contact with water, the interface beneath the droplet will attain one of the three different states—W1, W2, or W3 (
E
W2
<E
W1
,E
W3
θc>θos(w)>0−γow(r−1)/(r−φ)<Sos(w)<0 (7)
State W3 will be stable (i.e., the oil will encapsulate the texture) when:
EW3<EW1,EW2θos(w)=0γsw−γos−γow−Sos(w)≧0 (8)
and the droplet will displace the oil and be impaled by the textures (state W1) when:
E
W1
<E
W2
,E
W3
θos(w)>θcSos(w)<−γow(r−1)/(r−φ) (9)
Combining the above criteria along with the criterion for cloaking of the water droplet by the oil film described earlier, the various possible states can be organized in a regime map, which is shown
Roll-off angles of 5 μl droplets on silicone oil and BMIm impregnated textures while varying the post spacing b were measured experimentally. For comparison, the same textures without a lubricant (i.e., the conventional superhydrophobic case) were also evaluated. The results of these experiments are shown in
The effect of texture on the roll-off angle can be modelled by balancing gravitational forces with pinning forces. A force balance of a water droplet on a smooth solid surface at incipient motion gives ρwΩg sin α*≈2Rbγwa (cos θrec,ws(a)−cos θadv,ws(a)), where ρw is the density of the liquid droplet of volume Ω, g is the gravitational acceleration, Rb is the droplet base radius, and θadv,ws(a) and θrec,ws(a) are the advancing and receding contact angles of droplet in air on the smooth solid surface. To extend this treatment to our system, we recognize that pinning results from contact angle hysteresis of up to two contact lines: an oil-air-solid contact line with a pinning force per unit length given by γoa(cos θrec,os(a)−cos θadv,os(a)) and an oil-water-solid contact line with a pinning force per unit length given by γow(cos θrec,os(w)−cos θadv,os(w)). In some embodiments, the length of the contact line over which pinning occurs is expected to scale as Rbφ1/2, where φ1/2 is the fraction of the droplet perimeter (˜Rb) making contact with the emergent features of the textured substrate. Thus, a force balance tangential to the surface gives:
ρwΩg sin α*˜Rbφ1/2[γow(cos θrec,os(w)−cos θadv,os(w))+γoa cos θrec,os(a)−cos θadv,os(a))] (10)
Dividing Eq. (10) by Rbγwa, we obtain a non-dimensional expression:
Bo sin α*f(θ)˜φ1/2[γow(cos θrec,os(w)−cos θadv,os(w))+γoa(cos θrec,os(a)−cos θadv,os(a))]/γwa (11)
where
by assuming the droplet to be a spherical cap making an apparent contact angle θ with the surface.
is the Bond number, which compares the relative magnitude of gravitational forces to surface tension forces. Values for θrec,os(w), θadv,os(w), θrec,os(a), θadv,os(a), γow, γoa, and γwa are provided in Tables 2 and 3 below.
Described in the following paragraphs are embodiments that illustrate dynamics of droplet shedding. Once the gravitational forces on a droplet overcome the pinning forces, the velocity attained by the droplet determines how quickly it can be shed, which reflects the non-wetting performance of the surface. For a droplet of volume Ω this velocity may depend on both the contact line pinning and viscosity of the lubricant. In some embodiments, the steady-state shedding velocity V of water droplets may be measured using a high-speed camera while systematically varying lubricant dynamic viscosity μo, post spacing b, substrate tilt angle α, and droplet volume, Ω. These measurements are illustrated in
To explain these trends, it must first be determined whether the droplet is rolling or sliding. Referring now to the oil-water interface beneath the droplet as shown in
V
i
/V˜(1+(μohcm)/(μwt))−1 (12)
Since (μo/μw)(hcm/t)>>1 in some of the conducted experiments, Vi/V<<1, i.e., the oil-water interface moves at a negligibly small velocity relative to that of the droplet's center of mass. Thus, in some embodiments, the droplets being shed were rolling off the surface. The experiment was repeated with ground coffee particles being added to the water droplets, and the motion of the ground coffee particles was tracked with a high speed camera as the droplet moved across the surface. Particle trajectories, shown in
To determine the magnitude of V, the rate of change of gravitational potential energy as the droplet rolls down the incline with the total rate of energy dissipation due to contact line pining and viscous effects were balanced. The resulting energy balance gives:
V(Fg−Fp)˜μw∫Ω
where Fg and Fp represent the net gravitational and pinning forces acting on the droplet, the Ω terms are the volume over which viscous dissipation occurs, and the
The rate of viscous dissipation within the droplet (I) is primarily confined to the volume beneath its centre of mass and can be approximated as I˜μw(V/hcm)2Rb2hcm, where Rb is the base radius of the droplet. Applying geometrical relations for a spherical cap, Rb/hcm=g(θ)=4/3(sin θ)(2+cos θ)/(1+cos θ)2, yields: I˜μWV2Rbg(θ)
In some embodiments, the rate of viscous dissipation within the film (II) can be approximated as II˜μ0(Vi/t)2Rb2t. Since (μw/μ0)(t/hcm)<<1, from Eq.(12),
In some embodiments, the rate of viscous dissipation in the wetting ridge (III) can be approximated as III˜μ0(V/hridge)2Rbhridge2 since fluid velocities within the wetting ridge must scale as the velocities within the wetting ridge must scale as the velocity of the centre of mass and vanish at the solid surface, giving velocity gradients that scale as
Noting that Fg=μwΩg sin α and Fp=μwΩg sin α* and dividing both sides of Eq.(13) by RbVγwa yields.
where Ca=μwV/γwa, is the capillary number, Bo=Ω2/3μw g/γwa is the Bond number, and f(θ)=Ω1/3/Rb. Since (μw/μ0)(t/Rb)<<1, and μ0/μw>>g(θ) in some embodiments and experiments, Eq. (14) can be simplified to:
The datasets shown in
Droplets placed on lubricant-impregnated surfaces exhibit fundamentally different behavior compared to typical superhydrophobic surfaces. In some embodiments, these four-phase systems can have up to three different three-phase contact lines, giving up to twelve different thermodynamic configurations. In some embodiments, the lubricant film encapsulating the texture is stable only if it wets the texture completely (θ=0), otherwise portions of the textures dewet and emerge from the lubricant film. In some embodiments, complete encapsulation of the texture is desirable in order to eliminate pinning. In some embodiments, texture geometry and hierarchical features can be exploited to reduce the emergent areas and achieve roll-off angles close to those obtained with fully wetting lubricants. In some embodiments, droplets of low-viscosity liquids, such as water placed on these impregnated surfaces, roll rather than slip with velocities that vary inversely with lubricant viscosity. In some embodiments, additional parameters, such as droplet and texture size, as well as the substrate tilt angle, may be modeled to achieve desired droplet (and/or other substance) movement (e.g., rolling) properties and/or to deliver optimal non-wetting properties.
In order to achieve non-wetted states, it is often preferable to have low solid surface energy and low surface energy of the impregnated liquid compared to the nonwetted liquid. For example, surface energies below about 25 mJ/m2 are desired in some embodiments. Low surface energy liquids include certain hydrocarbon and fluorocarbon-based liquids, for example, silicone oil, perfluorocarbon liquids, perfluorinated vacuum oils (e.g., Krytox 1506 or Fromblin 06/6), fluorinated coolants such as perfluoro-tripentylamine (e.g., FC-70, sold by 3M, or FC-43), fluorinated ionic liquids that are immiscible with water, silicone oils comprising PDMS, and fluorinated silicone oils.
Examples of low surface energy solids include the following: silanes terminating in a hydrocarbon chain (such as octadecyltrichlorosilane), silanes terminating in a fluorocarbon chain (e.g., fluorosilane), thiols terminating in a hydrocarbon chain (such butanethiol), and thiols terminating in a fluorocarbon chain (e.g. perfluorodecane thiol). In certain embodiments, the surface comprises a low surface energy solid such as a fluoropolymer, for example, a silsesquioxane such as fluorodecyl polyhedral oligomeric silsesquioxane. In certain embodiments, the fluoropolymer is (or comprises) tetrafluoroethylene (ETFE), fluorinated ethylenepropylene copolymer (FEP), polyvinylidene fluoride (PVDF), perfluoroalkoxytetrafluoroethylene copolymer (PFA), polytetrafluoroethylene (PTFE), tetrafluoroethylene, perfluoromethylvinylether copolymer (MFA), ethylenechlorotrifluoroethylene copolymer (ECTFE), ethylene-tetrafluoroethylene copolymer (ETFE), perfluoropolyether, or Tecnoflon.
In
In certain embodiments, lubricant cloaking is desirable and is used a means for preventing environmental contamination, like a time capsule preserving the contents of the cloaked material. Cloaking can result in encasing of the material thereby cutting its access from the environment. This can be used for transporting materials (such as bioassays) across a length in a way that the material is not contaminated by the environment.
In certain embodiments, the amount of cloaking can be controlled by various lubricant properties such as viscosity, surface tension. Additionally or alternatively, the de-wetting of the cloaked material to release the material may be controlled. Thus, it is contemplated that a system in which a liquid is dispensed in the lubricating medium at one end, and upon reaching the other end is exposed to environment that causes the lubricant to uncloak.
In certain embodiments, an impregnating liquid is or comprises an ionic liquid. Ionic liquids have extremely low vapor pressures ˜(10−12 mmHg), and therefore they mitigate the concern of the lubricant loss through evaporation. In some embodiments, an impregnating liquid can be selected to have a Sow(a) less than 0. Exemplary impregnating liquids include, but are not limited to, tetrachloroethylene (perchloroethylene), phenyl isothiocyanate (phenyl mustard oil), bromobenzene, iodobenzene, o-bromotoluene, alpha-chloronaphthalene, alpha-bromonaphthalene, acetylene tetrabromide, 1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl) imide (BMIm), tribromohydrin (1,2,3-tribromopropane), tetradecane, cyclohexane, ethylene dibromide, carbon disulfide, bromoform, methylene iodide (diiodomethane), stanolax, Squibb's liquid petrolatum, p-bromotoluene, monobromobenzene, perchloroethylene, carbon disulfide, phenyl mustard oil, monoiodobenzene, alpha-monochloro-naphthalene, acetylene tetrabromide, aniline, butyl alcohol, isoamyl alcohol, n-heptyl alcohol, cresol, oleic acid, linoleic acid, amyl phthalate and any combination thereof.
In accordance with the present invention, exemplary solid features include, but are not limited to, polymeric solid, a ceramic solid, a fluorinated solid, an intermetallic solid, and a composite solid and any combination thereof. As demonstrated in
In some embodiments, solid features have a roughened surface. As used herein, θos(a)(is defined as the contact angle of oil (subscript ‘o’) on the textured solid (subscript ‘s’) in the presence of air (subscript ‘a’). In certain embodiments, the roughened surface of solid features provides stable impregnation of liquid therebetween or therewithin, when θos(v)>θc.
In certain embodiments, liquid-impregnated surfaces described herein have advantageous droplet roll-off properties that minimize the accumulation of the contacting liquid on the surfaces. Without being bound to any particular theory, a roll-off angle α of the liquid-impregnated surface in certain embodiments is less than 50°, less than 40°, less than 30°, less than 25°, or less than 20°.
Typically, flow through a pipe or channel, having an liquid-impregnate surface on its interior may be modeled according to Eq. (14):
where Q is the volumetric flow rate, R is pipe radius, h is the height of the texture, μ2 is the viscosity of lubricant and μ1 is the viscosity of the fluid flowing through the pipe. Δp/L is the pressure drop per L. Without being bound to any particular theory, it is believed that (h/R)(μ1/μ2) is greater than 1 for this to have a significant effect and this sets the height of the texture in relation to the viscosity ratio.
Although modeled for pipe flow, the general principals also apply to open systems, where R is replaced with the characteristic depth of the flowing material. The average velocity of the flow ˜Q/A, where A is the cross-sectional area of the flowing fluid.
For example, mayonnaise has a viscosity that approaches infinity at low shear rates (it is a Bingham plastic (a type of non-Newtonian material)), and therefore behaves like a solid as long as shear stress within it remains below a critical value. Whereas, for honey, which is Newtonian, the flow is much slower. For both systems, h and R are of the same order of magnitude, and μ2 is the same. However, since μhoney<<μmayonnaise, then
thus mayonnaise flows much more quickly out of the bottle than honey.
According to some embodiments of the present invention, an article includes an interior surface, which is at least partially enclosed (e.g., the article is an oil pipeline, other pipeline, consumer product container, other container) and adapted for containing or transferring a fluid of viscosity μ1, wherein the interior surface comprises a liquid-impregnated surface, said liquid-impregnated surface comprising an impregnating liquid and a matrix of solid features spaced sufficiently close to stably contain the impregnating liquid therebetween or therewithin, wherein the impregnating liquid comprises water (having viscosity μ2). In certain embodiments, μ1/μ2 is greater than about 1, about 0.5, or about 0.1.
In certain embodiments, the impregnating liquid comprises an additive to prevent or reduce evaporation of the impregnating liquid. The additive can be a surfactant. Exemplary surfactants include, but are not limited to, docosanoic acid, trans-13-docosenoic acid, cis-13-docosenoic acid, nonylphenoxy tri(ethyleneoxy) ethanol, methyl 12-hydroxyoctadecanate, 1-Tetracosanol, fluorochemical “L-1006”, and combination thereof. More details can be found in White, Ian. “Effect of Surfactants on the Evaporation of Water Close to 100 C.” Industrial & Engineering Chemistry Fundamentals 15.1 (1976): 53-59, the contents of which are incorporated herein by references. In addition or alternative, exemplary additives can be C16H33COOH, C17H33COOH, C18H33COOH, C19H33COOH, C14H29OH, C16H33OH, C18H37OH, C20H41OH, C22H45OH, C17H35COOCH3, C15H31COOC2H5, C16H33OC2H4OH, C18H37OC2H4OH, C20H41OC2H4OH, C22H45OC2H4OH, Sodium docosyl sulfate, poly(vinyl stearate), Poly(octadecyl acrylate), Poly(octadecyl methacrylate) and combination thereof. More details can be found in Barnes, Geoff T. “The potential for monolayers to reduce the evaporation of water from large water storages.” Agricultural Water Management 95.4 (2008): 339-353, the contents of which are incorporated herein by references.
The experiments of
BMIm impregnated textures showed roll-off angles that increase as the spacing decreases. This observation shows that pinning is non-negligible in this case, and occurs on the emergent post tops (
This Example demonstrates that condensation can be inhibited by preventing coalescence due to liquid cloaking.
a) shows an ESEM image sequence of condensation on a micropost surface impregnated with Krytox that has positive spreading coefficient on water (Sow>0). Condensation is inhibited as Krytox cloaks the condensed droplets.
Referring to
This Example demonstrates that condensation is inhibited by the decreased drainage rate of oil between neighboring water droplets, particularly where the oil has high viscosity.
Similar to the conditions described in Example 2, the temperature of the peltier cooler was set at −5° C. The room temperature was 20° C., and the dew point in the conditions was 12° C. As can be seen in
This Example demonstrates that frost can be inhibited by decreasing the drainage rate of oil from condensed structures, particularly where the oil has high viscosity.
Similar to the conditions described above, the temperature of the peltier cooler was set at −15° C. The experiments were conducted in low relative humidity environment such that the dew point in these conditions was −10° C. In these conditions, water vapor forms directly as frost on the peltier plate. However, on the impregnated surface, water vapor still forms as droplets, and frost. As can be seen in
This example demonstrates results of a series of experiments that included flowing a number of different external phases on a number of different solid surfaces impregnated with different impregnating liquids. The results of the conducted experiments are shown in Table 1 below. In Table 1 below, θos(a),receding is the receding contact angle of the impregnating liquid (e.g., silicone oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of air (subscript ‘a’), and where θos(e),receding is the receding contact angle of the impregnating liquid (e.g., silicone oil, subscript ‘o’) on the surface (subscript ‘s’) in the presence of the external phase (subscript ‘e’). θ*c=Cos−1(1/r) is the critical contact angle on the textured substrate and α* is the roll-off angle.
Slide off angles were measured using 500 μL volumes of the external fluid, except for water, for which 5 μL droplets were used. It was observed that in experiments where θos(e),rec<θ*c, the roll-off angles, α*, were low (e.g., less than or equal to 20°), whereas in cases where θrec,os(e)>θ*c, the roll-off angles, α*, were high (e.g., greater than or equal to 40°).
The silicon surfaces used in the experimental data shown in Table 1 above were 10 m square silicon posts (10×10×10 μm) with 10 m interpillar spacing. The 10 m square silicon microposts were patterned using photolithographic and etched using deep reactive ion etching (DRIE). The textured substrates were cleaned using piranha solution and were coated with octadecyltrichlorosilane (OTS from Sigma-Aldrich) using a solution deposition method.
The “WPTFE” surfaces shown in Table 1 above were composed of a 7:1 spray-coated mixture of a mixture of Teflon particles and Toko LF Dibloc Wax, sprayed onto a PET substrate. The carnauba wax (CW) surfaces were composed of PPE CW spray-coated onto a PET substrate. The impregnating liquids were propylene di(caprylate/caprate) (“PDC”), Krytox 1506, DOW PMX 200 silicone, oil, 10 cSt (“Silicone oil”) and Christo-lube EXP 101413-1 (“CL”). The external phases used were mayonnaise, toothpaste (e.g., Crest extra whitening), and red water based paint. Wenzel roughness, r, was measured using a Taylor hobson inferometer. Although precise estimates of φ could not be easily obtained, it was observed in the inferometer that φ was much less than 0.25 for all the impregnated surfaces described in the table, and tested, and using 0.25 as an upper bound on φ for our surfaces we determine that cos−1(1−φ)/(r−φ)=θc is no more than 5° greater than the values for θ*c.
The textured substrates used in the examples discussed below were square microposts etched in silicon using standard photolithography process; these square microposts are shown in
A second level of roughness was produced on microposts in some embodiments by creating nanograss, as shown in the SEM image of
The samples were then cleaned in a Piranha solution and treated with a low-energy silane (octadecyltrichlorosilane—OTS) by solution deposition. The samples were impregnated with lubricant by slowly dipping them into a reservoir of the lubricant. They were then withdrawn at speed S slow enough that capillary numbers Ca=μoS/γoa<10−5 to ensure that no excess fluid remained on the micropost tops where μo is the dynamic viscosity and γoa is the surface tension of the lubricant. In some embodiments, when the advancing angle θadv,os(a) is less than θc (see Table 4 below) the lubricant film will not spontaneously spread into the textured surface, as can be seen for BMIm (1-butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide) in
In order to determine whether or not the micropost tops were covered with lubricant after dipping, a LCFM (Olympus FV 300) was used. A florescent dye (DFSB-175, Risk Reactor, CA) was dissolved in the lubricant, and the textured substrate was impregnated with the dyed lubricant using dip coating, as explained above. The dye gets excited at wavelengths of ˜400 nm, and the resulting emittance was captured by the microscope. In some embodiments, as the focused laser beam scanned through the sample, areas containing dye appeared bright, indicating the presence of lubricant. This is shown, for example, in
Contact angles of silicone oil and BMIm were measured on the OTS-coated silicon surfaces in the presence of air and DI water using a Ramé-Hart Model 500 Advanced Goniometer/Tensiometer. The advancing (θadv,os(a), θadv,os(w)) and receding (θrec,os(a), θrec,os(w)) angles were taken as an average of at least 8 measurements. 5 μl droplets were deposited at a volume addition/subtraction rate of 0.2 μl s−1, yielding, in some embodiments, contact line velocities Vc less than 1 mm min−1. The resulting capillary numbers were Ca=μoVc/γo(i)<10−5 ensuring that the measured dynamic contact angles were essentially the same as contact angles obtained immediately after the contact line comes to rest. The measured contact angles are shown in Table 2 below.
Table 2 shows contact angle measurements on smooth OTS-treated silicon surfaces. In some embodiments, a surface that has been dipped in silicone oil maintains an oil film on the surface after a water droplet is deposited because the film cannot dewet the surface since θrec,os(w)=0°. Therefore, an oil-water-solid contact line cannot exist and pinning forces must be zero. Accordingly, the oil-solid-water pinning term in Eq.'s (10) and (11) above should be neglected if θrec,os(w)=0°. Similarly oil-solid-air pinning term should be neglected if θrec,os(a)=0°. For this reason, pinning forces are taken to be zero in
Table 3 shows surface and interfacial tension measurements and resulting spreading coefficients, Sow(a)=γwa−γow−γoa, of 9.34, 96.4, and 970 cP Dow Corning PMX 200 Silicone oils on water in air. Values of γow for silicone oil were taken from C. Y. Wang, R. V. Calabrese, AIChE J. 1986, 32, 667, in which the authors made measurements using the du Noüy ring method (described in du Noüy, P. Lecomte. “An interfacial tensiometer for universal use.” The Journal of general physiology 7.5 (1925): 625-631), and values of γoa were provided by Dow Corning. The surface and interfacial tensions for BMIm and Krytox were measured using the pendant drop method (described in Stauffer, C. E., The measurement of surface tension by the pendant drop technique. J. Phys. Chem. 1965, 69, 1933-1938). Here, γwa, γow, and γoa are the surface and interfacial tensions between phases at equilibrium, that is, after water and the lubricant become mutually saturated.
Table 4 shows texture parameters b, r, φ, and critical contact angles θc defined by θc=cos−1((1−φ)/(r−φ)), and θ*c=cos−1(1/r); h, a=10 μm for all substrates tested. The approximation θc≈θ*c, becomes more accurate as φ approaches zero. If the silicon substrate is not coated with OTS, θos(w)>θc, θ*c for both lubricants and all b values. Thus, water droplets should displace the lubricant and get impaled by the microposts leading to significant pinning, which was confirmed experimentally, as it was observed that such droplets did not roll-off of these surfaces.
While the invention has been particularly shown and described with reference to specific preferred embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
This application claims the benefit of, and incorporates herein by reference in their entireties, U.S. Provisional Patent Application No. 61/827,444, which was filed on May 24, 2013 and U.S. Provisional Patent Application No. 61/728,219, which was filed on Nov. 19, 2012.
Filing Document | Filing Date | Country | Kind |
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PCT/US13/70827 | 11/19/2013 | WO | 00 |
Number | Date | Country | |
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61728219 | Nov 2012 | US | |
61827444 | May 2013 | US |